MICRO CIRCULATORY MONITORING -

MICRO CIRCULATORY MONITORING

1. INTRODUCTION & CONCEPTUAL FRAMEWORK

What is the Microcirculation?

The microcirculation comprises:

Arterioles (<100 μm)
Capillaries (5–10 μm)
Venules (<100 μm)

Its primary function is:

Oxygen delivery
Nutrient exchange
Removal of metabolic waste
Immune cell trafficking
Endothelial signaling

Key concept:
Restoration of macrocirculation (MAP, CO) does NOT guarantee restoration of microcirculation.

This phenomenon is called hemodynamic incoherence.

2. PHYSIOLOGY OF MICROCIRCULATION

Determinants of Microcirculatory Flow

Component	Function
Arteriolar tone	Flow regulation
Capillary density	Diffusion surface
RBC deformability	Capillary transit
Endothelial function	Vasomotion, barrier
Glycocalyx	Shear sensing, permeability

Functional Capillary Density (FCD)

Number of perfused capillaries per tissue area
Strongest determinant of tissue oxygenation

Loss of FCD → tissue hypoxia despite normal DO₂

Oxygen Transport at Microcirculatory Level

Governed by Krogh cylinder model
Oxygen extraction depends on:

Capillary spacing
Transit time heterogeneity
RBC velocity

3. PATHOPHYSIOLOGY: MICROCIRCULATORY FAILURE

Mechanisms

1. Endothelial Dysfunction

NO dysregulation
Increased permeability
Leukocyte adhesion

2. Glycocalyx Shedding

Seen in:

Sepsis
Trauma
Ischemia-reperfusion

Leads to:

Capillary leak
Loss of mechanotransduction

3. Flow Heterogeneity

Patchy perfusion
Shunting
Areas of no-flow adjacent to normal flow

4. Microthrombosis

Sepsis-associated DIC
COVID-19
TTP/HUS

5. RBC Dysfunction

Reduced deformability
Sludging
Altered oxygen off-loading

4. HEMODYNAMIC INCOHERENCE

Definition

A state where:

Macro-hemodynamic variables normalize but microcirculation remains impaired

Seen in:

Septic shock
Post-cardiac surgery
Trauma resuscitation
VA-ECMO
Advanced heart failure

Clinical implication:

Raising MAP from 65 → 75 mmHg may not improve tissue perfusion

5. WHY MONITOR MICROCIRCULATION?

Limitations of Conventional Monitoring

Parameter	What it reflects	Limitation
MAP	Driving pressure	No tissue perfusion info
CVP	Volume status	Poor perfusion correlation
CO	Global flow	No distribution info
ScvO₂	Balance DO₂/VO₂	Misses regional hypoxia
Lactate	Metabolic stress	Late, non-specific

Microcirculation = Final Common Pathway of Shock

“Cells die not from hypotension, but from hypoxia.”

6. METHODS OF MICROCIRCULATORY MONITORING

A. DIRECT VISUALIZATION TECHNIQUES (GOLD STANDARD)

1. Handheld Vital Microscopy (HVM)

Evolution

OPS – Orthogonal Polarization Spectral Imaging
SDF – Sidestream Dark Field Imaging
IDF – Incident Dark Field Imaging (latest)

Incident Dark Field (IDF) Imaging

Principle

Green light (530 nm)
Absorbed by hemoglobin
RBCs appear dark against bright background

Site

Sublingual microcirculation

Thin mucosa
Easy access
Correlates with splanchnic perfusion

Parameters Assessed

Parameter	Meaning
Total Vessel Density (TVD)	Structural
Perfused Vessel Density (PVD)	Functional
Proportion of Perfused Vessels (PPV)	Flow adequacy
Microvascular Flow Index (MFI)	Flow quality
Heterogeneity Index (HI)	Flow distribution

Normal Values (Adult)

Parameter	Normal
MFI	≥ 2.6
PPV	> 90%
HI	< 0.5

Clinical Utility

Septic shock prognosis
Fluid responsiveness at micro level
Vasopressor titration
Transfusion decision-making

Limitations

Operator dependent
Offline analysis
Cost
Not continuous
Not bedside routine yet

B. INDIRECT MICROCIRCULATORY MONITORING

1. Near-Infrared Spectroscopy (NIRS)

Principle

Measures tissue oxygen saturation (StO₂)
Reflects balance of oxygen delivery & consumption

Sites

Thenar eminence
Forearm
Cerebral cortex

Vascular Occlusion Test (VOT)

Inflate cuff > systolic pressure
Measure:

Deoxygenation slope → oxygen consumption
Reoxygenation slope → microvascular recruitment

Interpretation

Finding	Meaning
Slow recovery	Microcirculatory dysfunction
Flat curve	Severe shock
Rapid overshoot	Good reserve

Limitations

Measures mixed arterial-venous signal
Influenced by edema, skin pigmentation
Not organ-specific

2. Peripheral Perfusion Indices

a. Capillary Refill Time (CRT)

Strong prognostic value (ANDROMEDA-SHOCK trial)
Target-guided resuscitation superior to lactate-guided

b. Skin Mottling Score

Reflects cutaneous hypoperfusion
Associated with mortality in septic shock

c. Temperature Gradient

Core-to-toe temperature difference

3. Venous-Arterial CO₂ Gap (P(v-a)CO₂)

Reflects microcirculatory flow adequacy
High gap (>6 mmHg):

Low flow states
Microvascular shunting

4. Lactate Kinetics

Surrogate of cellular hypoxia
Clearance >10% in 2–6 hours favorable

C. ORGAN-SPECIFIC MICROCIRCULATION

Organ	Marker
Brain	NIRS, PbtO₂
Kidney	Urine output, renal Doppler RI
Gut	Gastric tonometry (historical)
Liver	ICG clearance
Muscle	NIRS

7. MICROCIRCULATION IN SHOCK STATES

Septic Shock

↓ Capillary density
↑ Flow heterogeneity
Endothelial & glycocalyx damage

Microcirculatory failure may persist even after lactate normalization

Hemorrhagic Shock

Capillary derecruitment
Improved rapidly with volume & transfusion

Cardiogenic Shock

Low driving pressure
High venous pressure impairs capillary flow

Obstructive Shock

Venous congestion → impaired microflow

8. THERAPEUTIC IMPLICATIONS

Fluids

Improve microcirculation only if recruitable
Excess fluids → glycocalyx damage

Vasopressors

Norepinephrine:

May improve microcirculation if MAP low
Excess → vasoconstriction

Inotropes

Dobutamine may improve microflow independent of CO

RBC Transfusion

May improve microcirculation if baseline impaired
No benefit if normal microflow

Steroids

Improve endothelial responsiveness

9. FUTURE DIRECTIONS

AI-based automated microcirculatory analysis
Continuous bedside IDF devices
Microcirculation-guided resuscitation protocols
Integration with ECMO and shock platforms

10. KEY TAKEAWAYS

Microcirculation is the final determinant of tissue oxygenation
Hemodynamic coherence is not guaranteed
Sublingual IDF imaging is gold standard
CRT-guided resuscitation has outcome benefit
Normal MAP does not exclude tissue hypoxia